JPH0788155B2 - Safety belt - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention has two shoulder belts and one waist belt that can be connected to the shoulder belts via a bag, and the shoulder belt and the waist belt are at least indirect. The present invention relates to a safety belt of a type fixed to a vehicle frame, particularly a safety belt for racing and rally.

BACKGROUND OF THE INVENTION Safety belts with four, five or six mooring points, which are mainly used in racing cars, rally cars or sports cars, are known. This safety belt usually consists of two shoulder belts, one waist belt and often two leg belts.

The unique form and construction of such a safety belt ensures that the driver is kept in a favorable condition during the competition process.

Such a safety belt allows the driver's body to be tight and symmetrical with respect to the backrest by means of two shoulder belts which extend above the shoulders and at least one waist belt which surrounds and fastens the waist. Can be closely attached.

However, even with the above-mentioned safety belt, the safety of the driver is not sufficient, which is proved by a collision test (CRASH) conducted using a test car on which a doll with an instrument is placed. This collision test was conducted by EWG (European Economic Community) 77/541
According to the items set in relation to the collision at 40 km / n and the braking curve.

The most prominent problems and drawbacks confirmed in the above-mentioned experiment using the known perfect belt are as follows.

(1) The waist belt slides from the normal position over the iliac crest and moves to the soft part of the lower abdomen, causing serious injury (damage to the gluteus, liver, intestine, and spleen) in the lower abdomen.

(2) Acceleration applied to the rib cage 60g or more compared to the maximum allowable value of US Standard 208.

(3) Formula according to US Standard 208: HIC value (Hea
d Injury Criteria = Head injury assessment standard) is above the maximum allowable value. This HIC value is an international standard for testing the protection system of safety belt users.

When the sternum strongly collides against the safety belt at the time of collision, the HI value is strongly accelerated forward and twisted downward, and when the value applied to the rib cage exceeds the maximum allowable value, the head Is achieved by

The symmetrical forward extrusion of the upper body (chest, arm, head) during a collision divides the body's kinetic energy into two identical components E ₂ and E ₁ during a collision, which results in these components E ₂ and E 1. _{It has been determined that 1} is due to being received and absorbed at the same time t ₁ and t ₂ by both shoulder belts of the known safety belt. In this case, the shoulder is symmetrically pushed forward. Therefore, the symmetrical movement of the safety belt, which is assigned to the aforementioned low extension capacity, causes the aforementioned problems and drawbacks.

Therefore, when a safety belt with a leg belt is used, damage to internal organs can be reduced due to the presence of the leg belt.

In any case, the risk of groin damage in the event of a collision increases.

Even if a safety belt with 5 or 6 mooring points and leg belts is used, 60kg value and 1000 for the thorax
HIC values are often easily exceeded.

Problem to be Solved by the Invention The problem to be solved by the invention is to eliminate the problems and drawbacks of the known safety belts that result from the uniform movement of the body during a collision.

Means for Solving the Problems of the Invention Means for solving the problems of the present invention are as described in claim 1.

Embodiment The conversion of the different kinetic energy components E ₁ and E ₂ of the body in the mutually offset time zones t ₁ and t ₂ can be achieved in the following manner.

(1) At least one shoulder belt is provided with a device suitable for absorbing kinetic energy and changing the extension ability of one shoulder belt with respect to the extension ability of the other shoulder belt.

(2) Make sure that both shoulder belts have different stretch characteristics in the event of a collision.

The present invention will now be described with reference to the drawings.

In the embodiment shown in FIGS. 1 to 3, an S-shaped double loop F is formed in the length section of the shoulder belt 1 of the four-point safety belt SG. The S-shaped double loop F is sewn by the sewn portion 2 at the center. The sewn portion 2 is provided so as to convert kinetic energy and be torn when a predetermined load is applied.

A second embodiment of the energy converter is shown in FIGS. 4 and 5. In this case the shoulder belt 3 has three rapes 4,
Forming a bellows with 4 ', 4 ". Loops 4,4', 4"
Has a sewn portion 5,5 ', 5 "in the center of the length section. These sewn portions 5,5', 5" are also torn when a predetermined load is applied and the shoulder belt 3 The length is increased, and as a result, the kinetic energy is converted.

A third embodiment of a safety belt with an energy converter is shown in FIGS. 6 and 7.

This embodiment generally has end pawls 6 that can be moored to the vehicle body.

In this case, the end section 10 of the safety belt 11 must first be the end claw 6
Running substantially parallel to it, then deflected 180 ° below the elongated element 7 and passed through the elongated hole 7 in the end pawl 6.

The two-layer regions 9 and 12 formed in this way are
Have 13 and.

In this case, the energy converter is formed by an S-shaped sewn portion 13 which is provided in the area 9 arranged below the slot and which is torn when a predetermined load is applied.

FIGS. 8 and 9 show a fourth embodiment of a safety belt with an energy converter.

This embodiment has a two-layer area 21 sewn by a seam 17 formed by bending the end section 14 180 °. This two-layer area 21 is a clamp or sliding loop
19 is formed into an S-shape and is guided by two parallel slits 16 and 16 'of the fixed pawl 18.

The pin 20 located in the end section of the two-layer area 21 has a slit 1
At the end of the sliding process through 6,16 ', a two-layer area 21 is clamped.

In this fourth embodiment, the energy conversion is slit 16,1.
This is done by the sliding friction created when the two-layer area 21 slides in 6 '.

A fifth embodiment of the energy converter is shown in FIGS. 10 and 11. This energy converter mainly consists of a woven belt 22 with warp yarns 23. This belt 22
Has an elongation of at least 15% greater than that achievable with conventional safety belts when subjected to a tensile force of 400 kg.

The belt 22 can be manufactured, for example, from polypropylene yarn or other suitable elastic yarn. In this case, this thread must be the thread alone and without the addition of other components, which allows the belt 22 to have the desired elongation in order to convert the kinetic energy.

Next, the diagrams shown in FIGS. 12 to 19 will be described. In this case, in FIG. 12 and FIG. 13, the shoulder belt 1,
Shown is a time-dependent course of energy conversion for a CRASH experiment with a doll 24 secured by a non-stretching 4-point safety belt SG 1'converting energy.

Both curves show the course of the force (daN) simultaneously exerted on both, ie on the left and right shoulder belts 1,1 '.

The zero point is the origin of the coordinate axes. In this case, the time t is shown in 1/1000 seconds on the X-axis and the force is shown in daN on the Y-axis. The surfaces E ₁ and E ₂ surrounded by the curve are both shoulder belts 1 and 1 ′.
Associated with the energy converted by In this case E ₁
Is associated with the left shoulder belt 1 and E ₂ is associated with the right shoulder belt 1 '.

In the example shown, the dynamic symmetrical behavior of the two shoulder belts 1,1 'without energy converters is apparent. Especially noticeable are: (1) The maximum value of both shoulder belts 1,1 'is achieved at the same moment when t ₁ and t ₂ match, (2) The maximum value of the right shoulder belt 1 is It is the same for the left shoulder belt 1 ', (3) Both surfaces E ₁ and E ₂ have the same size.

Figures 14 and 15 show the right shoulder belt 1 or 3 (Figure 15
2) or 3) or an energy converter of the type shown in FIGS. 4 and 5 is provided, and the left shoulder belt 1 '(FIG. 14) is a normal type shoulder belt. Shown is a time-dependent course of energy conversion in a crash (CRASH) experiment with a doll fixed by a safety belt SG.

In the example shown, the dynamic asymmetrical movement of both shoulder belts 3, 1'is shown. Particularly noticeable are: (1) that the maximum value is achieved at different times (in this case the first maximum value t ₁ is related to the shoulder belt 1 ′ with no energy converter, The highest value t ₂ is related to the shoulder belt 3 with the energy converter), (2) the highest value of the shoulder belt 1 without the energy converter is higher, (3) both shoulder belts The energy converted by 3,1 'is very different, that is, both surfaces E ₁ and E ₂
E ₁ > E ₂ and they are very different from each other.

Further generation of low maximum values stitch 2 or 5,5 of the energy converter in t ₃ before the time point t ₁ and t ₂ ', seen on the basis of the fact that the 5 "torn.

Figures 16 and 17 show a doll fastened by a safety belt SG in which the energy converters of the type shown in Figures 6 to 9 are realized on the right shoulder belts 11,15. A time-dependent energy conversion diagram for a CRASH experiment with is shown.

A unique example shows the same asymmetric behavior of both shoulder belts. Of the two shoulder belts, the shoulder belt 1'associated with FIG. 16 does not have an energy converter, whereas the shoulder belts 11, 15 associated with FIG. 17 do.

Particularly noticeable are: (1) The first highest value is achieved when the highest value is different.
t ₁ relating to a shoulder belt without energy converter, the second highest value t ₂ relating to a shoulder belt with energy converter, (2) shoulder belt without energy converter. The maximum value of 1'is higher, and (3) the energy converted through the shoulder belts 11, 15 or 1'is significantly different when E ₁ > E ₂ .

For example, the magnitude class, the maximum value, the time and time to reach such a maximum value, the phase difference between both curves, the energy content is almost the same as in the diagrams of FIGS. 14 and 15. .

However, the premise is that the curves for the shoulder belts 11,15, that is to say the shoulder belts with energy converters, do not have a markedly low maximum, as shown in FIG. However, the above curve does not show that the force applied to the shoulder by the unavoidable biomechanical load by the shoulder belts 11 and 15 drops to zero. The curve, on the other hand, is constantly generated by the uniformly progressive energy converter 13 shown in FIGS. 6 and 7 or the energy converter 19 shown in FIGS. 8 and 9. The unchanging load flattening curve due to the tightened sliding friction is shown.

18 and 19, the stretchability of the right shoulder belt 22 is at least 15% higher than that of the right shoulder belt 1 '.
Shown is a time-dependent course of energy conversion during a collision experiment with the doll 24 secured by the safety belt 56 shown in FIGS.

As an example, the magnitude class, the maximum value, the time and time until the maximum value is reached, the phase difference between both curves, and the energy content are almost the same as the diagrams in FIGS. 14 and 15.

In this case the premise is a shoulder belt with an energy converter 23.
The curve associated with 22 is that it has no low peaks as shown in FIG. 15 and flat curves as shown in FIG. However, this curve accurately follows the bell-shaped course of the curve in Fig. 18, even though it has an extremely low maximum.

In the event of a collision, the rib cage will be pushed significantly forward by twisting, so that the doll 24 will rest on a spring-loaded, recessed, gentle series seat, such as those used in competition or rallies or sports cars. Even if installed, the pelvis will not slip below the waist belt 25.

Furthermore, for the above-mentioned reason, the severe head impact on the ribs is converted into slip having not only the longitudinal direction but also the lateral direction and the vertical direction, so that the g-number for the rib cage is avoided and the maximum value is 1000 HIC or less. Be reduced.

[Brief description of drawings]

1 is a schematic perspective view of a fitted safety belt having four mooring points, FIG. 2 is an enlarged view of a shoulder belt of the safety belt of FIG. 1, FIG. 3 is a side view of FIG. FIG. 4 is an enlarged partial view of a second embodiment of the safety belt shoulder belt of FIG. 1, FIG. 5 is a side view of FIG. 4, and FIG. 6 is a shoulder belt portion of the first safety belt. FIG. 7 is an enlarged view of the third embodiment, and FIG.
Fig. 8 is a longitudinal sectional view taken along the line VII-VII, Fig. 8 is a partially enlarged view of the fourth embodiment of the shoulder belt of the safety belt of Fig. 1, and Fig. 9 is a sectional view taken along the line IX-IX of Fig. 8. Fig. 10, Fig. 10 is a partially enlarged view of a fifth embodiment of the shoulder belt of the safety belt of Fig. 1, Fig. 11 is a longitudinal sectional view taken along line XX of Fig. 10, and Fig. 12 is known. Time course of energy conversion with time according to a prescribed collision experiment performed with a doll fastened by a safety belt,
FIG. 13 is a time-dependent curve of energy conversion by the collision test performed using the safety belts of FIGS. 2 to 5, and FIG. 14 is a safety belt of FIGS. 6 to 9. Fig. 15 is a time-dependent curve of energy conversion in the collision experiment using Fig. 15, Fig. 15 is a time-dependent curve of energy conversion in the collision experiment using the safety belt shown in Figs. 10 and 11. It is a figure. 1,1 '... Safety belt, 2 ... Seams, 3 ... Shoulder belts, 4,4', 4 "... Loops, 5,5 ', 5" ... Seams, 6 ...
… End claws, 7 …… Long holes, 8 …… Seams, 9 …… Double layer range, 10 …… End segment, 11 …… Shoulder belt, 12 …… Double layer range, 13 …… Seams, 14 …… Edge division, 15 ... Shoulder belt, 1
6,16 ′ …… slit, 17 …… seam, 18 …… fixing claw, 20
...... Pin, 21 …… Double layer area, 22 …… Belt, 23 …… Warp, 24 …… Rib, 25 …… Waist belt.

Claims (6)

[Claims] 1. A shoulder belt having two shoulder belts and one waist belt connectable to the shoulder belts via a buckle, wherein the shoulder belt and the waist belt are directly or indirectly fixed to a vehicle frame. A safety belt of the type in which at least one energy absorber is present on at least one shoulder belt, the safety belt wearer being absorbed by both shoulder belts (1,3,11,15,22 or 1 ') in the event of a collision The kinetic energy (E ₂ , E ₁ ) of each of the shoulder belts is different from each other, and the maximum value of the force generated on both shoulder belts is deviated in time, and both shoulder belts (1, 3, 11, 15,22 or 1 ') asymmetrically increases in length so that the twisting of the torso of the shoulder belt safety belt wearer and thus one shoulder is pushed forward relative to the other shoulder. Absorber is configured Characterized in that, safety belt. 2. At least one shoulder belt (1) is provided with at least one energy converter consisting of a double S-shaped loop (F), wherein said loop (F) is a lateral stitch (2). The safety belt according to claim 1, wherein the safety belt is sewn together with the safety belt. 3. A bellows-like energy converter is provided on at least one shoulder belt (3), and the energy converter is sewn at least by a lateral stitching portion (5,5 ', 5 ").
Safety belt according to claim 1, having two loops (4, 4 ', 4 "). 4. At least one shoulder belt (11) is provided with an energy converter consisting of a belt section (10) guided through an elongated hole (7) of a fastening (6), the belt section (10). 2. The safety belt according to claim 1, wherein the mutually overlapping areas (9, 12) are sewn together by sutured portions (13, 8) before and after the elongated hole (7). 5. An energy converter comprising a double belt (21) movable on at least one shoulder belt (15) through a pair of slits (16, 16 ') of a fixing member (18) under tightening resistance. The pin (20) penetrates the folded end of the double belt (21) in this case.
Safety belt as described. 6. The energy converter comprises a woven warp belt provided for one shoulder belt (22), which when exposed to a load of 400 kg the normal shoulder belt (1 '). The safety belt according to claim 1, which has an elongation property higher than that of) by 15%.